The BOMBARDIER* REGINA*

TALENT 2 REGINA Intercity X55 Environmental Product Declaration Environmental Product Declaration The BOMBARDIER* REGINA* Intercity X55 train reflects our dedication to developing products and services for sustainable mobility. With Environmental Product Declarations we provide an in depth analysis of the environmental impact our products have throughout their complete life cycle. Communicating Environmental Performance ISO 14025 We communicate the environmental performance of our products through Environmental Product Declarations (EPDs) following the international EPD system. Our EPDs are developed in line with the UNIFE Product Category Rules for Rail Vehicles (PCR 2009:05) as well as the principles and procedures of ISO 14025:2006. EPDs are part of the BOMBARDIER* ECO4* EcoEfficient Optimised Environmental Performance portfolio. They are based on Life Cycle Assessment methodology and function as an externally validated communication tool, providing complete transparency to the benefit of our customers and other stakeholders. The external validation is carried out by independent verifiers approved by the technical committee of the international EPD system and/or the EU Ecomanagement and Audit Scheme (EMAS). This EPD gives a detailed insight into the environmental impact of the REGINA Intercity X55 train throughout all phases of the vehicle life cycle. The Climate is Right for Trains

REGINA Intercity X55 Designed for Sustainable Mobility Material Content The REGINA Intercity X55 train is developed with a strong emphasis on our commitment to eliminating hazardous substances and related toxic emissions, providing a safer environment for our customers, passengers and employees. The Bombardier Controlled Substances list enables product designers to screen out such substances by identifying them throughout our supply chain and actively working towards eliminating them from our vehicles. Material [kg] Manufacturing Maintenance Total Metals 179 981,3 94 101,3 274 082,6 Polymers 9 157,8 177,0 9 334,8 Energy Efficiency Regenerative braking and ECO-driving, an energy saving electronic support for the driver, contribute to maximizing the energy efficiency of the REGINA Intercity X55 train at 8,04 kwh/km. Energy consumption data is based on a simulation run between Stockholm and Gothenburg including four stops with assumptions on vehicle auxiliary systems load based on EC Contract No. FP6-031458. The passenger load is set to 50% based on the estimated vehicle occupancy, giving 123 passengers per 4-car trainset. Regenerative braking is at approximately 10% due to the low number of stops and the fact that braking usually occurs at speeds over 150 km/h, requiring the extensive application of mechanical braking. Elastomers 7 416,4 3 352,4 10 768,8 200 Integrating Design for Environment to product development has a profound impact on Bombardier rail vehicles. The REGINA Intercity X55 train sets a high standard for environmentally sustainable rail transportation. Eco-efficient Intercity Travel The REGINA Intercity X55 provides passengers with a sustainable solution to intercity travel. It features a recoverability and recyclability rate of 98% and 93% respectively, high energy efficiency at 8,04 kwh per km and low standstill and pass-by noise levels. Overall environmental impact throughout the REGINA Intercity X55 train life cycle is inherently low with power supply at operation being sourced exclusively from renewable energy resources. The REGINA Intercity X55 train is designed in Västerås, Sweden to withstand the harsh conditions in Scandinavia. The consequent reliability reduces the environmental impact of maintenance and service throughout the REGINA Intercity X55 train life cycle. Bombardier Transportation Sweden has been certified according to ISO 14001 since 1999. Glass 7 051,5 53,3 7 104,8 Fluids 1 849,8 387,7 2 237,5 MONM 6 217,4 473,6 6 691,0 Others 15 241,3 10 570,3 25 811,6 Total 226 915,5 109 115,6 336 031,1 The REGINA Intercity X55 material composition and all material required for maintenance during a 25 year operation. Materials are classified according to ISO 22628:2002. The following chart shows an allocation of the REGINA Intercity X55 total vehicle mass to the five main product groups identified in PCR 2009:05, version 1.1 1. 21% 2% 35% Grams CO 2 equivalents / passenger-km Noise The REGINA Intercity X55 train is homologated according to TSI CR Noise (2006), see limits shown in the table below. The limits for noise are defined at a distance of 7,5 m from the center of the track and 1,2 m above the top of the rail. Noise 180 160 140 120 100 80 60 40 20 0 REGINA car Intercity X55 (petrol) car (diesel) car (ethanol) When compared to travelling with a car, bus or aircraft up to 95% of the resulting fossil CO 2 emissions per passenger/km could be avoided 2. bus db(a) aircraft REGINA Intercity X55 - Highlighted facts and figures Standstill noise < 68 Number of cars 4 Weight 226 916 kg 29% 13% Starting noise < 82 Pass-by noise at 80 km/h < 81 Capacity 245 seats Carbody 78 903 kg Pass-by noise at 200 km/h < 93 Max speed Energy consumption 200 km/h 8,04 kwh/km Interior, windows and doors 29 928 kg Bogies and running gear 66 042 kg Propulsion and electric equipment 48 383 kg 1 Product Category Rules (PCR) for preparing an environmental product declaration (EPD) for rail vehicles, UNCPC CODE: 495, PCR 2009:05, version 1.1, International EPD Consortium (IEC). Recoverability/ Recyclability 98% / 93% Comfort systems 3 660 kg 2 Calculations and assumptions are carried out by Bombardier and are based on the Network for Transport and Environment methods and data. The REGINA Intercity X55 modular structure according to PCR 2009:05, version 1.1 1. 2 REGINA Intercity X55 Environmental Product Declaration 3

A Life Cycle Perspective Environmental Profile of the REGINA Intercity X55 Raw material extraction Manufacturing Carbon Footprint Greenhouse gas (GHG) emissions throughout the REGINA Intercity X55 train life cycle are as low as 2,48 g of CO 2 equivalents when allocated to one passenger travelling for one km. Global Warming Potential (GWP 100 years)[kg CO 2 -equivalents / passenger-km.] 3,0 2,7 2,4 2,1 1,8 1,5 1,2 0,9 0,6 0,3 0 0,75 0,79 0,90 0,04 2,48 Total Energy and Material Resource Use Renewable and non-renewable energy and material resource use throughout the REGINA Intercity X55 train life cycle is detailed in the following charts as a percentage of the total for the entire lifecycle of the vehicle. The distinction between renewable and non-renewable energy and material resources is shown with green shades representing renewable resources and grey shades representing non-renewable resources. 1,2% 2,8% 1,2% 1,3% 2,3% Operation Raw material extraction and component production Use Final assembly 90,9% At Bombardier life cycle thinking is integrated to the design process, highlighting the significance of different design choices and the true overall environmental impact these choices have. Life Cycle Assessment Resource efficiency, waste generation and overall environmental impact have been analysed throughout all life cycle phases of the REGINA Intercity X55 train, following ISO 14040:2006 methodology. 3 Power supply Electric power to SJ AB rail vehicles is sourced exclusively from hydro power and wind power. Data from Vattenfall AB 4 was used to model propulsion and auxiliary energy consumption throughout the 25 year operational lifetime of the REGINA Intercity X55 train. 1% Contribution of each life cycle phase to the total mass of CO 2 equivalents emitted. Recyclability and Recoverability Using materials featuring high recyclability and considering disassembly early in the design phase maximise the overall recoverability of the REGINA Intercity X55 train. Material recycling and energy recovery aggregate to give a 98% recoverability rate. 5% 2% Hydro power Wind power Crude oil Hard coal Energy resource use throughout the REGINA Intercity X55 lifecycle shown as a percentage of the total calorific value. 2,8% 3,0% Lignite Natural gas Uranium Others The results are based on a 25 year vehicle lifetime operating between the cities of Stockholm and Gothenburg, with an average running distance of 400 000 km per year and a 50% passenger load factor. Propulsion and auxiliary energy consumption over the REGINA Intercity X55 train life cycle is based on the methodology and operational profiles used for the energy consumption simulation. The end of life phase of the life cycle is modeled according to technology available today. The potential benefit that could be gained from material recycling and energy recovery at this phase of the vehicle life cycle has not been considered and is not shown in the results. Hydro power 99% Wind power Material recycling Energy recovery Residues/Disposal 93% 3 Water Air Inert rock 17,1% 45,3% Metal ores Other minerals Others 3 Bombardier document: 3EST7 3320 Life Cycle Assessment of the REGINA Intercity X55. 4 Vattenfall AB: EPD of Electricity from Vattenfall's Nordic Hydropower. Power supply for the REGINA Intercity X55 resulting in emissions of 9,94g of CO2 equivalents per kwh. Projected recoverability at the end of life phase of the REGINA Intercity X55, following ISO 22628 methodology. Material resource use throughout the REGINA Intercity X55 lifecycle shown as a percentage of the total material resource mass. 4 REGINA Intercity X55 Environmental Product Declaration 5

Environmental Impact in Detail Upstream module Core module Downstream module Renewable resources Raw material extraction and Final assembly Total life cycle Use component production Renewable and non-renewable resource consumption, waste generation Material [kg/pass.km] 8,20E-03 and values for environmental impact categories provide a detailed insigh 1,23E-02 3,68E-03 3,40E-04 2,45E-02 Water 5,73E-03 8,78E-03 3,11E-03 1,44E-04 1,78E-02 Air 2,43E-03 3,51E-03 5,62E-04 1,96E-04 6,70E-03 Carbon dioxide 3,43E-05 1,75E-06 5,61E-06 3,83E-08 4,17E-05 Nitrogen 5,93E-07 7,96E-13 2,96E-09 2,38E-14 5,96E-07 Energy [MJ/pass.km] 1,41E-03 5,84E-04 2,87E-01 8,64E-06 2,89E-01 Biomass 1,50E-06 0,00E+00 1,80E-06 0,00E+00 3,30E-06 Primary energy from geothermics 4,59E-05 3,88E-07 7,63E-06 6,46E-09 5,39E-05 Primary energy from hydro power 1,00E-03 2,60E-04 2,87E-01 3,81E-06 2,88E-01 Primary energy from solar energy 3,21E-04 2,68E-05 5,68E-05 5,22E-07 4,05E-04 Primary energy from wind power 4,14E-05 2,96E-04 1,11E-05 4,29E-06 3,53E-04 Others 1,15E-06 1,01E-07 2,82E-08 3,13E-09 1,29E-06 Non-renewable resources Material [kg/pass.km] 5,18E-03 4,09E-03 5,34E-03 6,18E-05 1,47E-02 Inert rock 4,31E-03 4,06E-03 3,37E-03 5,93E-05 1,18E-02 Metal ores 7,20E-04 3,78E-07 3,77E-04 6,21E-09 1,10E-03 Non renewable elements 7,55E-06 3,29E-11 4,14E-09 1,86E-14 7,56E-06 Other minerals 1,41E-04 3,16E-05 1,59E-03 2,49E-06 1,77E-03 Energy [MJ/pass.km] 1,06E-02 1,17E-02 5,51E-03 1,84E-04 2,80E-02 Crude oil 2,47E-03 2,83E-04 9,63E-04 1,41E-05 3,73E-03 Hard coal 3,29E-03 2,69E-03 2,91E-03 3,98E-05 8,93E-03 Lignite 4,85E-04 3,05E-03 1,88E-04 4,45E-05 3,76E-03 Natural gas 2,29E-03 1,14E-03 7,45E-04 1,94E-05 4,19E-03 Uranium 2,08E-03 4,57E-03 6,98E-04 6,65E-05 7,42E-03 Definitions Acidification potential The aggregate measure of the acidifying potential of some substances, calculated through the conversion factor of sulphur oxides and nitrogen and ammonia into acidification equivalents (H + ion). Carbon footprint The carbon footprint of a passenger travelling for one km is the result of an allocation of the total amount of greenhouse gases (GHG) emitted over all phases of the vehicle life cycle. The total mass of emitted GHGs is allocated to CO 2 equivalents. Eutrophication potential The aggregate measure of the inland water eutrophication potential of some substances, calculated through the conversion factor of phosphorous and nitrogen compounds (waste water discharges and air emissions of NO x and NH 3 ) into phosphorous equivalents. Global warming potential The aggregate measure of the contribution to the greenhouse effect of some gases through their conversion into carbon dioxide equivalents. Life cycle assessment Life cycle assessment (LCA) is a technique assessing the environmental impact associated with all stages of a product's life from-cradle-to-grave (i.e., from raw material extraction through materials processing, manufacturing, distribution, use, repair and maintenance, and disposal or recycling). Ozone layer depletion potential The aggregate measure of the ozone layer depleting potential of some substances, calculated through the conversion factor of halogenated hydrocarbons that contribute to the depletion of the ozone layer into CFC -11 equivalents. Waste [kg/pass.km] 6,61E-03 4,09E-03 3,37E-03 7,79E-05 1,42E-02 Hazardous waste 5,92E-06 1,93E-06 2,71E-06 3,14E-06 1,37E-05 Nonhazardous waste 6,61E-03 4,09E-03 3,37E-03 7,48E-05 1,41E-02 Environmental impact categories [pass.km] Acidification Potential (AP) [kg SO 2 -Equiv.] 3,98E-06 1,36E-06 1,45E-06 2,89E-08 6,82E-06 Eutrophication Potential (EP) [kg Phosphate-Equiv.] 7,06E-07 1,76E-07 7,88E-06 3,79E-09 8,77E-06 Global Warming Potential (GWP 100 years) [kg CO 2 -Equiv.] 7,54E-04 7,94E-04 8,95E-04 3,96E-05 2,48E-03 Ozone Layer Depletion Potential (ODP) [kg R11-Equiv.] 5,88E-11 1,31E-10 1,51E-11 1,91E-12 2,07E-10 Ozone Creation Potential (POCP) [kg Ethene-Equiv.] 3,48E-07 3,20E-07 2,35E-07 2,18E-09 9,05E-07 Photochemical ozone creation potential The aggregate measure of the ground level ozone creation potential of some substances, calculated through the conversion factor of ethylene equivalents that contribute to the formation of photochemical oxidants. Recyclability and recoverability The recyclability and the recoverability rate of a new rail vehicle are expressed as a percentage by mass of the rail vehicle that can potentially be recycled, reused or both (recyclability rate), or recovered, reused or both (recoverability rate). 6 REGINA Intercity X55 Environmental Product Declaration 7

Design for Environment The integration of environmental sustainability into product development is fundamental at Bombardier, where it has a core function in designing state of the art rail transportation equipment. Applying a complete life cycle perspective to vehicle design is central to our product responsibility strategy. Maximising energy and resource efficiency, eliminating hazardous substances and related toxic emissions as well as enhancing the overall product recyclability rate is the result of a high quality working process applied to product design and cascaded down our supply chain. The Bombardier Transportation Design for Environment (DfE) Centre of Competence, together with the DfE expert network, acts as a catalyst by providing the essential tools, expertise and central coordination in projects worldwide. More information on Design for Environment and Environmental Product Declarations at Bombardier is available at: www.csr.bombardier.com/en/products/our-approach. PCR review was conducted by the technical committee of the international EPD system: Joakim Thornéus (Chair) Swedish Environmental Management Council email: joakim@environdec.com Independent verification of the declaration and data, in accordance to ISO 14025:2006. Internal External Martin Erlandsson, Individual Verifier, c/o IVL Swedish Environmental Research Ltd., Box 21060, SE-100 31 Stockholm, Sweden Tel: +46 8 598 563 30, Fax: +46 8 598 563 90 email: martin.erlandsson@ivl.se Environmental Product Declarations within the same product category, but from different programs may not be comparable. This EPD is valid until 2015-01-10 Registration No. S-P-00191 UN CPC 49520 Date: 2012-01-10 More information on the international EPD system is available at www.environdec.com. If you no longer require this fact sheet, please recycle it responsibly. 2011, Bombardier Inc. or its subsidiaries. All rights reserved. Printed in Germany/11053/MLM/12-2011/en Bombardier Transportation Sweden AB Department MLM/TAVE Centre of Competence Design for Environment Östra Ringvägen 2, SE-721 73 VÄSTERÅS Sweden Tel +46 10 852 0000 Fax +46 10 852 7111 www.bombardier.com *Trademark(s) of Bombardier Inc. or its subsidiaries.